CN217364459U - Food processor - Google Patents

Abstract

The utility model discloses a food processor, which comprises a frame, a functional component and a power device; the functional component is arranged on the base, the power device is arranged in the base, and the power device is used for providing driving force for the functional component; the power device comprises a support, a motor assembly and a gear box assembly, wherein the motor assembly and the gear box assembly are integrated on the support, and the support is connected with the base so as to install the power device on the base. Through setting up the support promptly to with motor element and gear box subassembly etc. integrated on the support in advance, make support, motor element and gear box subassembly integrated after a holistic power device, whole assembly can be accomplished in being connected of rethread support and frame. Compare need be connected motor element and gear box subassembly with the frame respectively among the prior art, the food processor of this disclosure only needs to be connected the support that has integrateed motor element and gear box subassembly with the frame and can accomplish the equipment, and assembly efficiency is higher.

Description

Food processor

Technical Field

The present disclosure relates to the field of food processing technology, and more particularly, to a food processor.

Background

In the related art, a food processor generally includes a housing, a motor assembly, and a gear box assembly. During specific assembly, the motor assembly and the gearbox assembly need to be respectively installed in the machine base, so that the assembly efficiency is low.

SUMMERY OF THE UTILITY MODEL

To solve the above technical problem or at least partially solve the above technical problem, the present disclosure provides a food processor.

The present disclosure provides a food processor, comprising a base, a functional assembly and a power device; the functional component is arranged on the base, the power device is arranged in the base, and the power device is used for providing driving force for the functional component;

the power device comprises a support, a motor assembly and a gear box assembly, wherein the motor assembly and the gear box assembly are integrated on the support, and the support is connected with the base so as to install the power device on the base.

The food processor provided by the disclosure is through setting up the support to with motor element and gear box subassembly etc. integrated on the support in advance, make support, motor element and gear box subassembly integrated after a holistic power device, whole assembly can be accomplished to the connection of rethread support and frame. Compare need be connected motor element and gear box subassembly with the frame respectively among the prior art, the food processor of this disclosure only need be connected the support that has integrateed motor element and gear box subassembly with the frame and can accomplish the equipment. Therefore, the food processor of the present disclosure is simple to assemble and has high assembly efficiency.

According to one embodiment of the disclosure, a first fastening hole is formed in the bracket, a second fastening hole is formed in the position, corresponding to the first fastening hole, of the machine base, and the bracket is fixed to the machine base through a fastening piece arranged in the first fastening hole and the second fastening hole;

the first fastening holes are arranged at intervals along the periphery of the bracket; the second fastening holes are multiple and correspond to the first fastening holes one by one.

In this technical scheme, connect through setting up the fastener between support and the frame for the connection steadiness between frame and the support is better. The first fastening hole and the second fastening hole through setting up connecting bracket and frame are a plurality of for the connection reliability between bracket and the frame is showing and is promoting.

According to an embodiment of the present disclosure, the motor assembly and the gear box assembly are detachably connected to both ends of the bracket, respectively, and the motor assembly and the gear box assembly are in transmission connection.

In this technical scheme, through with motor element and gear box subassembly detachably connection respectively at the both ends of support, be convenient for dismantle maintenance or change it when can making in any one of motor element or the gear box subassembly take place to damage, need not to lead to the support that integrated motor element and gear box subassembly is whole to be scrapped and leads to the higher problem of maintenance cost.

According to one embodiment of the present disclosure, the stand includes a first stand and a second stand connected to the first stand; the first frame body extends along the vertical direction and is connected with the motor assembly; the second support body extends along the horizontal direction and is connected with the gear box assembly.

In the technical scheme, the setting support is provided with two parts, namely a first support body and a second support body, and the first support body is arranged to vertically extend so as to be convenient for being connected with a motor assembly in the base; in a similar way, the second frame body is arranged to extend horizontally so as to be connected with the gear box component in the machine base conveniently.

According to one embodiment of the present disclosure, a first connection hole is formed in the first frame body, a second connection hole is formed in a position, corresponding to the first connection hole, of the motor assembly, and the motor assembly is connected to the first frame body through a first connection piece arranged in the first connection hole and the second connection hole; and/or, be provided with the third connecting hole on the second support body, gear box subassembly on with the position that the third connecting hole corresponds is provided with the fourth connecting hole, gear box subassembly is through locating the third connecting hole with second connecting piece in the fourth connecting hole is connected on the second support body.

In this technical scheme, set up and connect through first connecting piece between motor element and the first support, can be so that the connection steadiness between motor element and the first support is better. Set up and connect through the second connecting piece between gearbox subassembly and the second support, can be so that the connection steadiness between gearbox subassembly and the second support is better.

According to an embodiment of the present disclosure, the first frame body and the second frame body are integrally formed.

In this technical scheme, through setting up first support body and second support body integrated into one piece, not only be convenient for manufacturing and can ensure the structural strength of support.

According to one embodiment of the present disclosure, the gearbox assembly includes a housing and a drive shaft and bevel gear assembly disposed within the housing; the shell is connected with the bracket;

one end of the transmission shaft protruding out of the shell is connected with an output shaft of the motor assembly, and the bevel gear assembly is arranged at the other end of the transmission shaft.

In the technical scheme, the shell and the bracket which are arranged on the gear box component are connected in advance, so that the process of connecting the shell and the base of the gear box component can be omitted. In addition, be connected with the driving motor transmission through setting up the transmission shaft, and the bevel gear subassembly is located on the transmission shaft for motor element drive transmission shaft can drive the bevel gear subassembly when rotating and rotate, thereby makes transmission shaft and bevel gear subassembly can transmit not equidirectional power, in order to drive different functional unit.

According to an embodiment of the present disclosure, the functional component includes a mixing tank and an extrusion cylinder communicated with the mixing tank, a mixing knife is arranged in the mixing tank, an extrusion screw is arranged in the extrusion cylinder, and the mixing knife and the extrusion screw are in transmission connection with the gear box component.

In the technical scheme, the gear box component can directly or indirectly provide driving forces in different directions for the extrusion screw and the stirring knife through the extrusion screw connected with the gear box component and the stirring knife connected with the gear box component, so that the stirring knife can stir flour in the stirring barrel to form dough; and the extrusion screw can extrude the stirred dough wadding to finish dough making.

According to an embodiment of the present disclosure, the base includes a main body having a mounting cavity, and a bottom cover disposed at a bottom of the main body, the bottom of the main body having an opening for the gear box assembly to be mounted in the mounting cavity, and the bottom cover being configured to cover the opening.

In this technical scheme, through setting up the bottom of main part and having the opening, can assemble the gear box subassembly from the below in the main part from this opening to the problem that the assembly still need set up the shielding cover plate structure from the top has been saved.

According to an embodiment of the present disclosure, the gear box assembly is provided below the agitator.

In this technical scheme, through locating the below of agitator with the gear box subassembly to can be convenient for assemble the gear box subassembly from the below of agitator, saved and still set up the shielding cover plate structure on the gear box subassembly.

According to one embodiment of the present disclosure, the food processor is a noodle maker.

In this technical scheme, through setting up the support to with motor element and gear box subassembly etc. integrated on the support in advance, make support, motor element and gear box subassembly after integrated as a holistic power device, whole assembly can be accomplished in the connection of rethread support and frame. Compare need be connected motor element and gear box subassembly respectively with the frame among the prior art, the support that this disclosed noodle only need will integrate motor element and gear box subassembly is connected with the frame and can be accomplished the equipment. Therefore, the noodle maker is simple to assemble and high in assembling efficiency.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and together with the description, serve to explain the principles of the disclosure.

In order to more clearly illustrate the embodiments or technical solutions in the prior art of the present disclosure, the drawings used in the description of the embodiments or prior art will be briefly described below, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive exercise.

FIG. 1 is a front perspective view of a food processor according to an embodiment of the present disclosure;

FIG. 2 is a rear perspective view of a food processor according to an embodiment of the present disclosure;

FIG. 3 is an exploded view of a food processor according to an embodiment of the present disclosure;

FIG. 4 is an exploded view of the housing and power unit of the food processor according to the embodiment of the present disclosure;

FIG. 5 is a schematic view of a power plant of the food processor according to the embodiment of the present disclosure;

FIG. 6 is an interior side view of a food processor according to an embodiment of the present disclosure.

100, a machine base; 101. a first mounting portion; 102. a second mounting portion; 1021. a first sub-mount portion; 1022. a second sub-mount section; 103. an accommodating cavity; 104. a mounting cavity; 105. A noodle outlet; 106. an air outlet; 107. a heat generating film; 110. a bottom cover; 1101. a clamping groove; 120. an electronic scale; 130. operating the display panel assembly; 200. a top trim portion; 300. a decorative piece; 400. a noodle bucket assembly; 410. a cylinder cover; 420. a stirring barrel; 430. a stirring knife; 500. A water tank assembly; 600. a power plant; 610. a support; 6101. a first fastening hole; 6102. a first frame body; 6103. a second frame body; 6104. a first connection hole; 6105. a third connection hole; 620. A motor assembly; 6201. a second connection hole; 6202. a convex structure; 630. a gearbox assembly; 6301. a drive shaft; 6302. a housing; 700. a water pump integrated system; 800. a noodle outlet assembly; 810. extruding the screw; 820. a die piece; 830. an extrusion cylinder; 900. a wind guide and drainage system; 910. a drawer assembly; 920. a drawer support; 930. a fan; 940. a fan guard.

Detailed Description

In order that the above objects, features and advantages of the present disclosure may be more clearly understood, aspects of the present disclosure will be further described below. It should be noted that the embodiments and features of the embodiments of the present disclosure may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure, but the present disclosure may be practiced in other ways than those described herein; it is to be understood that the embodiments disclosed in the specification are only a few embodiments of the present disclosure, and not all embodiments.

Referring to fig. 1 to 6, the present embodiment provides a food processor, which may be a noodle maker. Specifically, the food processor includes a housing 100, functional components, and a power unit 600.

Illustratively, the functional components may be the noodle bucket assembly 400 and the noodle outlet assembly 800. The dough barrel assembly 400 comprises a stirring barrel 420 and a stirring blade 430 arranged in the stirring barrel 420. The dough exit assembly 800 includes an extrusion barrel 830 and an extrusion screw 810 disposed within the extrusion barrel 830. In specific implementation, the functional components are disposed on the base 100, for example, the mixing tank 420 is disposed on the base 100, the extrusion cylinder 830 is disposed on the base 100 and located at the bottom of the mixing tank 420, and the extrusion cylinder 830 is communicated with the mixing tank 420. The power device 600 is arranged in the machine base 100 and is in transmission connection with the stirring blade 430 and the extrusion screw 810, so as to drive the stirring blade 430 to rotate to knead the dough or drive the extrusion screw 810 to rotate to extrude the kneaded dough.

In particular, the power device 600 of the present embodiment may include a bracket 610, a motor assembly 620, and a gear box assembly 630. By arranging the bracket 610 and pre-integrating the motor assembly 620, the gear box assembly 630 and the like on the bracket 610, the motor assembly 620 and the gear box assembly 630 are integrated into a whole power device 600, and then the whole assembly can be completed by connecting the bracket 610 and the stand 100.

Compared with the prior art that the motor assembly 620 and the gearbox assembly 630 need to be connected with the base 100 respectively, the food processor of the embodiment can be assembled only by connecting the bracket 610 integrated with the motor assembly 620 and the gearbox assembly 630 with the base 100. Therefore, the food processor of the embodiment is simple to assemble and high in assembly efficiency.

In a specific implementation, as shown in fig. 3 to 5, a first fastening hole 6101 may be provided on the bracket 610, and a second fastening hole matched with the first fastening hole 6101 is provided at a position on the base 100 corresponding to the first fastening hole 6101, and the fastening member sequentially penetrates through the first fastening hole 6101 and the second fastening hole, so that the bracket 610 is connected in the base 100. That is to say, in the power device 600 of the present embodiment, the motor assembly 620 and the gear box assembly 630 are integrated on the bracket 610 in advance, and during assembly, the power device 600 can be assembled in the machine base 100 only by connecting the bracket 610 to the machine base 100 through the fastening member, so that the assembly is simple and efficient.

For example, the first fastening hole 6101 and the second fastening hole may be threaded holes, the fastening member may be a screw or a bolt, and the bracket 610 and the base 100 are connected by providing a screw or a bolt, so that the connection stability between the base 100 and the bracket 610 may be better.

Illustratively, the first fastening hole 6101 and the second fastening hole may be both smooth holes, and the fastening member may be a pin. Or the bracket 610 and the base 100 may be fixed by clamping. For the specific connection between the bracket 610 and the base 100, reference may be made to the above example of the present embodiment, which is not specifically limited in this embodiment.

In order to enhance the connection reliability of the bracket 610 and the housing 100, in this embodiment, a plurality of first fastening holes 6101 may be provided, and the plurality of first fastening holes 6101 are provided at intervals along the outer circumference of the bracket 610. Accordingly, a plurality of second fastening holes may be provided, and the second fastening holes correspond to the first fastening holes 6101 one to one.

For example, the first fastening hole 6101 and the second fastening hole may each be 2, or 4 or more. By providing a plurality of the first fastening holes 6101 and the second fastening holes connecting the bracket 610 and the housing 100, the reliability of the connection between the bracket 610 and the housing 100 is significantly improved. The number of the first fastening holes 6101 and the second fastening holes can be set according to actual needs.

In concrete implementation, as shown in fig. 3, the left end of the support 610 is connected to the motor assembly 620, the right end of the support 610 is connected to the gear box assembly 630, and the motor assembly 620 is in transmission connection with the gear box assembly 630, so that the gear box assembly 630 is driven by the motor assembly 620 to drive the functional assembly to rotate to realize corresponding operation. That is, the motor assembly 620 and the gear box assembly 630 are detachably coupled to the left and right ends of the bracket 610, respectively, so that the motor assembly 620 and the gear box assembly 630 can be assembled by reasonably using the space of the bracket 610.

In addition, the left ends of the motor assembly 620 and the bracket 610 and the right ends of the gear box assembly 630 and the bracket 610 can be detachably connected, so that the motor assembly 620 or the gear box assembly 630 can be conveniently detached for maintenance or replacement.

In a specific implementation, referring to fig. 3, the bracket 610 includes a first frame 6102 and a second frame 6103 connected to the first frame 6102. Specifically, the first frame body 6102 is located at the left end of the second frame body 6103, the first frame body 6102 extends along the vertical direction and is connected to the motor assembly 620, and the second frame body 6103 extends along the horizontal direction and is connected to the gear box assembly 630.

For the connection structure of the first frame 6102 and the motor assembly 620, it is: the first frame body 6102 is provided with a first connection hole 6104, a second connection hole 6201 is disposed at a position on the motor assembly 620 corresponding to the first connection hole 6104, and the first connection member sequentially penetrates through the first connection hole 6104 and the second connection hole 6201, so as to detachably connect the motor assembly 620 to the first frame body 6102. That is to say, the motor assembly 620 and the first frame body 6102 are connected through the first connecting member, so that the connection stability between the motor assembly 620 and the first frame body 6102 is good.

For example, the first connecting hole 6104 and the second connecting hole 6201 may be threaded holes, the first connecting member may be a screw or a bolt, and the first frame body 6102 and the motor assembly 620 are connected by setting a screw or a bolt, so that the connection stability between the first frame body 6102 and the motor assembly 620 may be better.

For example, the first connection hole 6104 and the second connection hole 6201 may be both unthreaded holes, and the first connection member is, for example, a pin. Or the first frame body 6102 and the motor assembly 620 may be connected and fixed in a clamping manner. For the specific connection between the first frame 6102 and the motor assembly 620, reference may be made to the above-mentioned example of the present embodiment, which is not specifically limited to this.

In order to enhance the connection reliability between the motor assembly 620 and the first frame 6102, in the embodiment, a plurality of first connection holes 6104 may be provided, and the plurality of first connection holes 6104 are arranged at intervals along the outer circumference of the first frame 6102. Correspondingly, a plurality of second connection holes 6201 may be provided, and the second connection holes 6201 correspond to the first connection holes 6104 one by one.

For example, the first connection hole 6104 and the second connection hole 6201 may be 2 each, or 4 or more. By providing a plurality of first and second connection holes 6104 and 6201 connecting the first frame 6102 and the motor assembly 620, the connection reliability between the first frame 6102 and the motor assembly 620 is significantly improved. The number of the first connection holes 6104 and the second connection holes 6201 may be set according to actual needs.

The connection structure of the second frame body 6103 and the gear box assembly 630 is: the second frame body 6103 is provided with a third connecting hole 6105, a fourth connecting hole is provided at a position corresponding to the third connecting hole 6105 on the gear box assembly 630, and the second connecting member sequentially penetrates through the third connecting hole 6105 and the fourth connecting hole, so that the gear box assembly 630 is detachably connected to the second frame body 6103. That is, the gear box assembly 630 and the second frame body 6103 are connected by the second connecting member, so that the gear box assembly 630 and the second frame body 6103 can be connected stably.

For example, the third connecting hole 6105 and the fourth connecting hole may be both threaded holes, the second connecting member may be a screw or a bolt, and the second frame body 6103 and the gear box assembly 630 are connected by setting a screw or a bolt, so that the connection stability between the second frame body 6103 and the gear box assembly 630 may be better.

For example, the third connecting hole 6105 and the fourth connecting hole may be both unthreaded holes, and the second connecting member is, for example, a pin. Or the second frame body 6103 and the gear box assembly 630 may be connected and fixed in a clamping manner. The specific connection between the second frame body 6103 and the gear box assembly 630 can refer to the above-mentioned example of the present embodiment, which is not limited in this regard.

In order to enhance the connection reliability between the gear box assembly 630 and the second frame body 6103, in this embodiment, a plurality of third connection holes 6105 may be provided, and the plurality of third connection holes 6105 are provided at intervals along the outer circumference of the second frame body 6103. Accordingly, a plurality of fourth connection holes may be provided, and the fourth connection holes correspond to the third connection holes 6105 one to one.

Illustratively, the third connecting hole 6105 and the fourth connecting hole may be 2, or 4 or more. By providing a plurality of third and fourth connecting holes 6105 and 630 connecting the second frame body 6103 and the gear case assembly 630, the connection reliability between the second frame body 6103 and the gear case assembly 630 is significantly improved. The number of the third connecting holes 6105 and the fourth connecting holes can be set according to actual needs.

In specific implementation, the first frame body 6102 and the second frame body 6103 may be integrally formed, so as to facilitate processing and manufacturing and ensure the overall structural strength of the bracket 610.

In a specific implementation, as shown in fig. 4 and 5, the gearbox assembly 630 includes a housing 6302, and a transmission shaft 6301 and a bevel gear assembly disposed in the housing 6302, and the housing 6302 of the gearbox assembly 630 is connected to the bracket 610 in advance, so that a process of connecting the housing 6302 of the gearbox assembly 630 to the base 100 can be omitted. In addition, through setting up transmission shaft 6301 and motor element 620 transmission connection, and the bevel gear subassembly is located on transmission shaft 6301 for motor element 620 can drive the bevel gear subassembly when driving transmission shaft 6301 and rotate, thereby makes transmission shaft 6301 and bevel gear subassembly can drive the not equidirectional power of transmission.

In specific implementation, the left end of the transmission shaft 6301 is connected with the output shaft of the motor assembly 620, the extrusion screw 810 is connected with the right end of the transmission shaft 6301, and the bevel gear assembly is arranged on the transmission shaft 6301 and is connected with the stirring shaft of the stirring knife 430, so that the transmission shaft 6301 can directly or indirectly provide driving forces in different directions for the extrusion screw 810 and the stirring knife 430, and the stirring knife 430 can stir flour in the stirring barrel 420 to form dough wadding; and the extrusion screw 810 can extrude the stirred dough-flake to complete dough making.

More specifically, the bevel gear assembly includes two bevel gears, i.e., a first bevel gear and a second bevel gear, the first bevel gear is disposed on the transmission shaft 6301, the second bevel gear is engaged with the first bevel gear, and the second bevel gear is connected with the stirring shaft. The specific driving process is as follows: when kneading is required, the motor assembly 620 may rotate in a forward direction, for example, to drive the transmission shaft 6301 to rotate and drive the first bevel gear to rotate, so that the second bevel gear engaged with the first bevel gear rotates, the stirring shaft is driven to rotate by the rotation of the second bevel gear, and the stirring blade 430 on the stirring shaft rotates to knead dough. When the extrusion surface is required, the motor assembly 620 may rotate in the opposite direction, so as to drive the driving shaft 6301 to rotate and drive the extrusion screw 810 connected with the driving shaft 6301 to rotate, so as to extrude the cotton wool from the die head piece 820.

In specific implementation, the base 100 includes a main body and a bottom cover 110 disposed at the bottom of the main body, the top of the bottom cover 110 has an assembly cavity, and the motor assembly 620 is at least partially accommodated in the assembly cavity, so that the motor assembly 620 can be fixed and limited by the assembly cavity, and the position stability of the motor assembly 620 is ensured.

In addition, the contour of the assembly cavity may be configured to match the outer contour of the motor assembly 620, so that the motor assembly 620 is not shaken after being disposed in the assembly cavity, thereby ensuring the position of the motor assembly 620 in the housing 100.

In specific implementation, a convex structure 6202 extending towards the outer side wall is arranged on the outer side wall of one end, close to the bottom cover 110, of the motor assembly 620, a clamping groove 1101 clamped with the convex structure 6202 is formed at a position, corresponding to the convex structure 6202, on the bottom cover 110, so that connection is achieved through matching of the convex structure 6202 and the clamping groove 1101.

Referring to fig. 3, the gear box assembly 630 is provided under the agitation can 420. In addition, the housing 100 includes a main body having a mounting cavity, and a bottom cover 110 disposed at a bottom of the main body, the bottom of the main body having an opening for the gear box assembly 630 to be mounted in the mounting cavity, the bottom cover 110 covering the opening. By providing the bottom of the body with an opening from which the gearbox assembly 630 can be fitted into the body from below, the problem of the need to provide a blanking cover structure for fitting from above is eliminated.

Referring to the direction shown in fig. 1, the right half of the housing 100 is defined as a first mounting portion 101, the left half of the housing 100 is defined as a second mounting portion 102, and the second mounting portion 102 is higher than the first mounting portion 101. That is, referring to the z direction shown in fig. 1, the top of the second mounting portion 102 is higher than the top of the first mounting portion 101, and the bottoms of the first mounting portion 101 and the second mounting portion 102 are flush, so that the first mounting portion 101 and the second mounting portion 102 jointly enclose the accommodating cavity 103 with an L-shaped structure, and the accommodating cavity 103 can be used for mounting the mixing tank 420. That is, the right half of the housing 100 is used to mount the agitator 420. The extruding cylinder 830 is arranged at the bottom of the stirring barrel 420 and is communicated with the stirring barrel 420, namely, a flour inlet communicated with the stirring barrel 420 is formed in the extruding cylinder 830, flour and water are stirred in the stirring barrel 420 through the stirring knife 430 and are kneaded to form flour flocs, and the flour flocs can enter the extruding cylinder 830 from the flour inlet to be extruded and molded, so that the noodle preparation is completed.

In addition, as shown in fig. 1 and 2, it may be provided that the second mounting part 102 includes a first sub-mounting part 1021 and a second sub-mounting part 1022 disposed at a rear side of the first sub-mounting part 1021. By disposing the top of the second sub-mounting part 1022 to be recessed downward, the height of the first sub-mounting part 1021 is higher than that of the second sub-mounting part 1022, that is, the top of the first sub-mounting part 1021 is higher than that of the second sub-mounting part 1022, and then the first sub-mounting part 1021 and the second sub-mounting part 1022 together enclose an L-shaped structure as shown in fig. 2, that is, an L-shaped mounting cavity 104 for mounting the water tank assembly 500 of the food processor.

By providing the garnish 300 on the side of the second mounting portion 102 facing away from the first mounting portion 101, the garnish 300 can slide upward from the bottom of the second mounting portion 102 to attach to the outer side wall of the second mounting portion 102 facing away from the first mounting portion 101. That is, referring to the drawing direction shown in fig. 1, the deco 300 is slid upward from the bottom of the second mounting portion 102 and attached to the left side wall of the second mounting portion 102.

In the embodiment, the decoration piece 300 is arranged to decorate the base 100, so that the appearance aesthetic feeling of the noodle maker is improved; meanwhile, the decoration piece 300 is connected to the outer side wall of the second mounting part 102, which is far away from the first mounting part 101, from the bottom of the second mounting part 102 in a sliding mode, so that the decoration piece 300 can be mounted on the base 100 more quickly and conveniently. If one of the decoration 300 or the base 100 itself is broken or damaged, the decoration 300 and the base 100 can be detached, and only the damaged part needs to be replaced, so that the base 100 and the decoration 300 are prevented from being scrapped integrally, and the cost is saved.

Further, the noodle maker in the present embodiment further includes a top decoration portion 200. By covering the top decoration part 200 on the top of the first sub-mounting part 1021 and referring to the drawing direction shown in fig. 1, the left and right ends of the top decoration part 200 extend downward and are attached to the two opposite sides of the second mounting part 102, so that the outer surface of the second mounting part 102 is decorated to improve the appearance of the noodle maker. In addition, both ends of the top decoration portion 200 are detachably connected with corresponding positions of the side surfaces of the second mounting portion 102 to ensure easy detachment and replacement of the top decoration portion 200 to satisfy different needs of users.

In concrete implementation, the top decoration part 200 is detachably connected to the top of the first sub-installation part 1021, so that the top of the first sub-installation part 1021 is covered, the top decoration part 200 can be covered on the top of the first sub-installation part 1021, and the outer surface of the first sub-installation part 1021 is decorated, so that the appearance of the noodle maker is improved.

In addition, the outer contour of the noodle machine formed by the top decoration part 200 and the machine base 100 can be smooth and regular; and the top decoration part 200 may have different colors, thereby satisfying the user's demands for the exterior color of the noodle maker, etc., and having better popularization.

Specifically, referring to fig. 1 and 3, the noodle maker may further include a water pump integration system. The base 100 is provided at the bottom thereof with a bottom cover 110, thereby enclosing a closed chamber together with the base 100 for accommodating the power unit 600, the water pump integrated system, etc.

When dough making is carried out, the water pump integrated system 700 is used for communicating the dough barrel assembly 400 with the water tank assembly 500, so that water in the water tank assembly 500 is conveyed into the dough barrel assembly 400 through the water pump integrated system 700, then a proper amount of flour can be added into the dough barrel assembly 400, then the power device 600 drives the stirring knife 430 in the dough barrel assembly 400 to rotate so as to carry out dough making or dough kneading, and after the dough making or dough kneading is finished, the power device 600 drives the extrusion screw 810 to extrude and send out dough, so that one-time dough making can be finished.

That is, an electronic scale 120 may be disposed outside the base 100 of the noodle maker of this embodiment for weighing the noodles, so that the flour may be accurately proportioned with water to achieve the preparation of the noodles. The noodle maker can be provided with an operation display board assembly 130, so that the operation display board assembly 130 can be operated to control dough making, dough standing and dough outlet, specifically, the menu keys on the operation display board assembly 130 are operated to control dough making, dough standing and dough outlet.

The specific operation flow is as follows: the electronic scale 120 is connected with the noodle maker through a Bluetooth or signal line. When the electronic scale 120 weighs flour, a menu button on the operation display panel assembly 130 is pressed to select a corresponding control command, and then the weighed flour is poured into the mixing tank 420 of the dough barrel assembly 400, and then the barrel cover 410 of the dough barrel assembly 400 is covered. Corresponding instructions are selected, a program is started, the noodle maker starts to operate and execute the corresponding instructions, and the water pump integration system 700 transfers water in the water tank assembly 500 into the noodle barrel of the noodle barrel assembly 400. The power device 600 drives the stirring knife 430 to rotate, the stirring knife 430 stirs the flour and the water to form cotton wool, and then the power device 600 drives the extrusion screw 810 to convey the cotton wool to the die head piece 820 of the flour outlet assembly 800 for extrusion molding, so that one-time flour making is completed.

The power plant 600 may in particular provide two forces in vertical and equilibrium directions. Providing a force in a vertical direction to the stirring blade 430 to stir the flour and water (or other liquid) into a dough wadding; the balanced direction provides force to the extrusion screw 810 for extrusion.

During concrete implementation, the water pump integrated system 700 is located in the base 100 and above the power device 600, and is located on one side of the water tank assembly 500, so that the position of the water tank assembly 500 is closer, the internal structure of the whole noodle maker is compact, and related waterway errors are reduced. During the concrete operation, through the button of pressing operation display panel subassembly 160, then can realize automatic adding water, the water pump of water pump integrated system starts this moment, gets into the water pump through the water pipe of water pump integrated system 700 with the water in the water tank set spare 500, and the frame 100 is flowed to in the face bucket subassembly 400 again through the water pump again.

In addition, referring to fig. 3, the noodle maker of the present embodiment may further include an air guiding and draining system 900 disposed below the barrel assembly 400 and abutting against the noodle outlet 105 of the frame 100. The wind guiding and draining system 900 is used for sucking wind from the bottom of the base 100 through the fan 930 and discharging the wind through the wind outlet 106 of the base 100, and the wind outlet 106 corresponds to the position of the noodle outlet 105, so that the extruded noodles are dried in the air, and the adhesion of food is reduced. In a specific implementation, the wind guiding and draining system 900 specifically includes a drawer assembly 910, a drawer support 920, a fan 930, and a fan cover 940. The drawer assembly 910 is installed in the drawer support 920, and the fan 930 is used for conveying air entering from the bottom of the bottom cover 110 to the air outlet 106 to air-dry the noodles extruded from the noodle outlet 105.

In addition, as shown in fig. 3, the bottom of the noodle bucket assembly 400 can be further provided with a heating film 107, so that a noodle standing function can be realized.

It is noted that, in this document, relational terms such as "first" and "second," and the like, may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The foregoing are merely exemplary embodiments of the present disclosure, which enable those skilled in the art to understand or practice the present disclosure. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the disclosure. Thus, the present disclosure is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (11)

1. A food processor is characterized by comprising a machine base, a functional component and a power device; the functional component is arranged on the base, the power device is arranged in the base, and the power device is used for providing driving force for the functional component;

the power device comprises a support, a motor assembly and a gear box assembly, wherein the motor assembly and the gear box assembly are integrated on the support, and the support is connected with the base so as to install the power device on the base.

2. The food processor of claim 1, wherein the bracket is provided with a first fastening hole, the base is provided with a second fastening hole at a position corresponding to the first fastening hole, and the bracket is fixed to the base by a fastening member provided in the first fastening hole and the second fastening hole;

the first fastening holes are arranged at intervals along the periphery of the bracket; the second fastening holes are multiple and correspond to the first fastening holes one by one.

3. The food processor of claim 1, wherein the motor assembly and the gear box assembly are removably coupled to respective ends of the frame, and the motor assembly and the gear box assembly are drivingly coupled.

4. The food processor of claim 1, wherein the rack includes a first rack and a second rack coupled to the first rack; the first frame body extends along the vertical direction and is connected with the motor assembly; the second support body extends along the horizontal direction and is connected with the gear box assembly.

5. The food processor of claim 4, wherein the first frame body is provided with a first connecting hole, the motor assembly is provided with a second connecting hole at a position corresponding to the first connecting hole, and the motor assembly is connected to the first frame body through a first connecting member provided in the first connecting hole and the second connecting hole; and/or the presence of a gas in the gas,

the gear box is characterized in that a third connecting hole is formed in the second frame body, a fourth connecting hole is formed in a position, corresponding to the third connecting hole, of the gear box component, and the gear box component is connected to the second frame body through a second connecting piece in the third connecting hole and the fourth connecting hole.

6. The food processor of claim 4, wherein the first and second racks are integrally formed.

7. The food processor of claim 4, wherein the gearbox assembly includes a housing and a drive shaft and bevel gear assembly disposed within the housing; the shell is connected with the bracket;

one end of the transmission shaft protruding out of the shell is connected with an output shaft of the motor assembly, and the bevel gear assembly is arranged at the other end of the transmission shaft.

8. The food processor of any one of claims 1 to 7, wherein the functional component comprises a mixing barrel and a squeezing barrel communicated with the mixing barrel, a mixing knife is arranged in the mixing barrel, a squeezing screw is arranged in the squeezing barrel, and the mixing knife and the squeezing screw are in transmission connection with the gear box component.

9. The food processor of claim 8, wherein the housing includes a body having a mounting cavity and a bottom cover disposed at a bottom of the body, the bottom of the body having an opening for the gear box assembly to fit into the mounting cavity, the bottom cover for covering the opening.

10. The food processor of claim 9, wherein the gear box assembly is disposed below the agitator.

11. A food processor as claimed in any one of claims 1 to 7, wherein the food processor is a noodle maker.

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